|Publication number||US5102040 A|
|Application number||US 07/678,555|
|Publication date||Apr 7, 1992|
|Filing date||Mar 28, 1991|
|Priority date||Mar 28, 1991|
|Publication number||07678555, 678555, US 5102040 A, US 5102040A, US-A-5102040, US5102040 A, US5102040A|
|Inventors||William J. Harvey|
|Original Assignee||At&T Bell Laboratories|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (6), Non-Patent Citations (4), Referenced by (106), Classifications (12), Legal Events (4)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This invention relates to a method, and associated apparatus, for controlling one or more fans within an electronics enclosure to achieve enhanced cooling and cooling control.
Electronic equipment housed within an enclosure is often cooled by one or more fans which are operated to draw or blow air through the enclosure past the equipment therein. In the past, the fan(s) within such enclosures were usually operated at their rated speed (RPM) at all times, the rated speed being selected to assure sufficient air flow to avoid overheating under worst-case conditions. Operating the fan(s) at their rated speed at all times is inefficient and wasteful of energy because worst-case conditions infrequently occur. Moreover, fan operation at full speed is usually accompanied by a high noise factor, which is generally undesirable.
In an effort to avoid the above-enumerated disadvantages, controllers have been developed for varying the fan speed (RPM). Present day fan controllers generally operate to vary the fan speed continuously, or between a low and a high speed, either in accordance with the temperature of the air entering the enclosure (Ti), or the temperature (Te) of the air leaving the enclosure, or with the temperature difference ΔT between Te and Ti. Under normal operating conditions, each of these approaches accomplishes reduced fan speed under normal operating conditions, thereby lowering energy consumption and fan noise.
Variable fan-speed operation in accordance with each of these approaches, while preferable to fixed-speed fan operation, nonetheless incurs difficulties. For example, varying the fan speed in accordance with the air inlet temperature Ti does not account for any diminution in the volume of air drawn through the enclosure as a result of a clogged fan filter or a blocked air inlet. In addition, regulating the fan speed in accordance with Ti does not account for any increase in heat load, due to an increase in amount of electronic equipment within the enclosure or a fan failure.
By comparison, varying the fan speed in accordance with ΔT or Te does account for a diminished air flow, as well as an increased heat load. However, varying the fan speed in accordance with ΔT does not take into account an increase in the value of the inlet air temperature Ti. As the inlet air temperature Ti rises, it is possible that ΔT may not increase. However as the inlet air temperature rises, the temperature of the electronics within the enclosure may likewise rise, giving rise for a need for greater cooling. However, if the fan speed is regulated in accordance with the actual value of ΔT, the fan speed will not change. Under these circumstances, electronic equipment overheating may occur. The disadvantage to controlling the fan speed in accordance with the air exhaust temperature Te is that the technique provides no indication as to what conditions may have changed. For example, controlling the fan speed in accordance with Te would not indicate whether the increase in heat load was due to a blocked fan, an increase in the amount of electronics, etc.
Thus, there is a need for a technique for varying the fan speed which accounts for changes in both Ti and ΔT to achieve enhanced cooling and control.
Briefly, in accordance with a preferred embodiment of the invention, a method is disclosed for controlling the speed of at least one fan forcing air through an enclosure containing heat-generating equipment to enhance the cooling of such equipment. The method is initiated by first establishing a relationship between the temperature of air entering the enclosure (Ti), and the maximum allowable temperature difference ΔT for the equipment. As the heat-generating equipment within the enclosure is operated, both the inlet and exhaust temperature Ti and Te are continuously measured. The difference between the actual value of ΔT and the maximum allowable value of ΔT, as determined from the prescribed relationship between the maximum allowable ΔT and Ti, is determined. The speed of the fan(s) in the enclosure is adjusted such that the actual value of ΔT does not exceed the maximum allowable value of ΔT by more than a predetermined tolerance factor. The foregoing approach advantageously accounts for both a diminution of air flow and increased heat volume as well as an increase in the ambient air temperature.
FIG. 1 is a partially cut-away view in perspective of an enclosure according to the prior art which contains at least one fan for forcing air through the enclosure to cool equipment contained therein;
FIG. 2 is a block diagram of a system, in accordance with the present invention, for varying the speed of the fans of FIG. 1 in accordance with both the inlet air temperature and ΔT, the difference between the inlet and exhaust air temperatures;
FIG. 3 is graphical representation of the maximum allowable temperature differential between the inlet and exhaust air temperatures versus inlet air temperature for the enclosure of FIG. 1; and
FIG. 4 is a graphical representation of the fan speed versus temperature differential for the fans of FIG. 1.
FIG. 1 is a partially cut-away perspective view of a prior art enclosure 10 which is adapted to hold one or more pieces of electronic equipment 12. In a preferred embodiment, each piece of electronic equipment takes the form of a plug-in card 12 comprised of a component-carrying circuit board (not shown). Each card 12 is adapted to slide along, and seat in, a separate one of a set of slots or channels 14 within a set of shelves 16 secured in the enclosure 10. As each plug-in card 12 is inserted in its respective channel 14, the card makes electrical contact a backplane 18 which serves to selectively connect the card to others within the enclosure 10.
The plug-in cards 12, when operated, generate heat, which in the aggregate can be significant. If the heat generated by the plug-in cards 12 was allowed to remain trapped in the enclosure 10, one or more of the plug-in cards could become overheated and cease operating. To avoid overheating of the plug-in cards 12, air is forced through the enclosure to provide cooling. To this end, an air inlet/outlet 20 is provided into the enclosure, typically in the front thereof near the base where the air is coolest. One or more fans 22 are typically mounted in the back wall of the enclosure to draw air from the inlet 20 through the enclosure 10. An air filter 23 is provided within the inlet 20 to filter the air drawn through, and then exhausted from, the enclosure by the fans 22.
Generally speaking, the heat q within the enclosure 10 is constant and is proportional to the product of the air flow through the enclosure 10 and the temperature difference ΔT between the air temperature Ti at the inlet 20 and the temperature Te of the air exhausted by the fans 22. The air flow through the enclosure 10 varies with the speed of the fans 22 so that as the fan speed increases, so does the air flow. In the past, the fans 22 within the enclosure were operated continuously at their rated speeds so the fans could move sufficient air for worst-case conditions. Constant operation of the fans 22 at their rated speed at normal conditions is wasteful of energy. Moreover, continuous operation of the fans 22 at their rated speed often creates a large amount of unwanted noise.
In FIG. 2, there is shown a block schematic diagram of a control system 24, in accordance with the invention, for controlling the fans 22 to vary their speed in accordance with both the air temperature Ti at the inlet 20 and the temperature difference (ΔT) between Te and Ti. The fan control system 24 comprises at least one temperature-sensing device 26 (e.g., a thermistor or the like) positioned adjacent to the air inlet 20 of FIG. 1 for sensing the inlet air temperature Ti. At least one temperature sensing device 28, of a construction similar to the temperature sensor 26, is positioned within the stream of air exhausted by the fans 28 to measure the exhaust air temperature Te. As indicated by the dashed lines in FIG. 2, additional temperature sensors 26 and 28 may be provided for measuring the inlet and exhaust air temperature Ti and Te at different locations within the inlet 20 and the exhaust air stream, respectively.
The inlet and exhaust temperature sensors 26 and 28 are coupled to a microprocessor 30 which processes the signals from the sensors to establish the inlet and exhaust air temperatures Ti and Te. (In the case of multiple inlet and exhaust temperature sensors 26 and 28, the microprocessor 30 will average the signals received from the inlet and exhaust temperature sensors 26 and 28 to obtain a more accurate measure of inlet and exhaust air temperatures Ti and Te, respectively.) The microprocessor 30 is programmed, in the manner described below, to generate a fan control signal in accordance with the difference between ΔT, the actual temperature difference between Te and Ti, and ΔTm, the maximum allowable temperature difference between Te and Ti for the current value of the inlet air temperature Ti. The fan control signal produced by the microprocessor 30 is output to a motor control unit which excites the fans 22 in accordance with the fan control signal to adjust the fan speed in accordance with the difference between ΔT and ΔTm .
The manner in which the microprocessor 30 controls the speed of the fans 22 may best be understood by reference to FIG. 3, in which the solid line represents the graphical relationship between the maximum allowable temperature difference ΔTm versus inlet temperature Ti for the enclosure of FIG. 1. The actual temperature difference (ΔT) between Ti and Te corresponds to the heat being dissipated within the enclosure 10 and the air flow therethrough. Obviously, if the temperature difference in the enclosure 10 becomes too great, then overheating of the plug-in cards 12 will occur. Thus, for the plug-in cards 12, there is a maximum temperature difference (ΔTm) that can be tolerated.
Simply adjusting the speed of the fans 22 to maintain a constant ΔT will not avoid overheating of the plug-in cards 14 of FIG. 1 because as the inlet air temperature Ti increases, the maximum temperature difference (ΔTm) that can be tolerated decreases. The reason why is that as the inlet air temperature Ti rises, the degree to which the plug-in cards 12 of FIG. 1 will be cooled by this higher temperature air is accordingly reduced. The relationship between the maximum allowable temperature difference ΔTm and the inlet air temperature Ti depends on the cooling requirements for the particular configuration and number of plug-in cards 12 in the enclosure of FIG. 1. For the enclosure 10 of the preferred embodiment, the relationship between the maximum allowable ΔTm and Ti is given by the formula
ΔTm =C1 Ti +C2 (1)
where C1 and C2 are constants depending on the nature of the plug-in cards 12 and the conditions under which they are being operated. The relationship between ΔTm and Ti given by eq. (1) for the enclosure of FIG. 1 is represented by the solid line in the plot of FIG. 3. A different electronic enclosure having a different configuration of electronic equipment will likely have different cooling requirements, and, therefore, the values of C1 and C2 will be different. Accordingly, the relationship between the maximum allowable value of ΔTm versus Ti for such an enclosure will be different from that shown in FIG. 3.
Control of the fans 22 by the microprocessor 30 in accordance with the invention is accomplished by first establishing the desired relationship between the maximum allowable value of ΔTm versus Ti and then entering the relationship into the microprocessor at the outset of operation. There are several ways in which this can be done. For example, eq. (1) can be entered directly. Thus, during operation, the maximum allowable value of ΔTm for the currently measured value of Ti must be calculated using the Ti value obtained from the sensor(s) 26. Alternatively, a look-up table containing corresponding values of the maximum allowable ΔTm for each of a plurality of possible values of Ti can be entered. Thus for a given measured value of Ti, the corresponding maximum allowable value of ΔTm can easily be obtained from the previously entered look-up table.
Once the desired relationship between ΔTm and Ti has been entered into the microprocessor 30, then actual control of the fans 22 is commenced, when the plug-in cards 12 of FIG. 1 are initially energized, by initially energizing the fans so that they operate at minimal rate, typically about one-half their rated speed. As the fans 22 operate, the inlet and exhaust air temperatures Ti and Te are monitored by the microprocessor 30 by sensing the signals from the sensors 26 and 28, respectively. The actual value of ΔT is then calculated and compared to the maximum allowable (i.e., prescribed) value of ΔTm given by the previously entered relationship between ΔTm and Ti, as shown in FIG. 3.
If the actual value of ΔT exceeds ΔTm by more than a predetermined tolerance factor, typically 4° C. (represented by the dashed line in FIG. 3), then the microprocessor 30 signals the motor control 32 to increase the speed of the fans 22. By increasing the fan speed, the air flow in the enclosure 10 increases, thereby increasing the cooling of the plug-in cards 12 of FIG. 1 which reduces the temperature difference ΔT.
The steps of sensing Ti and Te, calculating the actual value of ΔT, comparing the actual value to the value of ΔTm, and increasing the fan speed if the value of ΔTm exceeds the actual value of ΔT, are carried out periodically at a very rapid rate, typically once every few microseconds. In this way, the fan speed will be automatically increased, very rapidly, as the actual value of ΔT rises above the value of ΔTm corresponding to the current value of Ti.
Controlling the fan speed in the manner described has several distinct advantages over prior art schemes because the present approach not only advantageously accounts for an increase in heat load as well as a diminution of air flow, but also accounts an increase in the inlet temperature Ti. If the heat load within the enclosure 10 increases, for example, as a result of an increase in the number of plug-in cards 12, or if the air flow is diminished, as a result of the inlet 20 of FIG. 1 becoming blocked or the air filter 23 becoming clogged, then the actual value of ΔT will increase. An increase in the actual value of ΔT causes the difference between ΔT and ΔTm to increase. Consequently, the microprocesor 30 causes the speed of the fans 22 to increase which increases the air flow into the enclosure 10, thereby reducing the temperature therein.
Should the air inlet temperature increase Ti rise, then given the relationship between ΔTm and Ti shown by the solid line in FIG. 3, ΔTm will decrease. If the actual value of ΔT remains unchanged, or changes less than ΔTm as a result of the rise in Ti, then the microprocessor 30 will also increase the fan speed.
As should be appreciated, it is not possible to continually increase the speed of the fans 22 in response to an increase between ΔT and ΔTm. Eventually, the fans 22 will reach their rated speed beyond which continuous higher speed operation cannot be sustained. At their rated speed (typically 3350 RPM), the fans 22 can only circulate enough air to achieve a particular ΔT which may be greater (or less) than ΔTm for the corresponding present value of Ti. Likewise, when the fans 22 are operated at their minimum speed (about 1350 RPM), the air flow achievable at that fan speed will be sufficient to achieve an actual ΔT which may be greater or less than ΔTm for that speed. FIG. 4 shows the relationship between the speed (RPM) of the fans 22 and ΔTa, the minimum achievable value of ΔT for that fan speed. The solid line in FIG. 4 represents the relationship between fan speed (RPM) and ΔTa achievable at sea level, assuming the air filter 23 within the inlet 20 is clean. The dashed line represents the relationship between the fan speed and ΔTa which is achievable at an altitude of 10,000 feet, also assuming a clean filter 23. The dash-dotted line in FIG. 4 represents an alarm condition which occurs when the actual value of ΔT exceeds the value of ΔTa for the corresponding fan speed. As with the relationship between ΔTm and Ti, the relationship between ΔTa and fan speed, given by the dash-dotted line in FIG. 4, is entered to the memory of the microprocessor 30 at the outset of operation.
To be able to sense the alarm condition shown in FIG. 4, each of the fans 22 of FIG. 2 has a tachometer sensor 34 associated with it for monitoring the fan's speed. The tachometer sensor 34 associated with each fan 22 is coupled to the microprocessor 30 which continuously monitors the actual fan speed along with the inlet and exhaust air temperature Ti and Te, respectively. Should the actual value of ΔT exceed the alarm limit value of ΔTa, given by the dash-dotted line in FIG. 4, then such a condition is reported.
Further, by sensing the speed of the fans 22, the microprocessor 30 can ascertain clogging of the air filter 23 within the inlet. As clogging begins, ΔT will remain constant at a constant temperature Ti but the fan speed will increase. Should the fan speed increase above a predetermined limit, then the filter 21 is likely clogged and such a condition is reported. Also, by sensing the speed of each of the fans 22, a blockage or failure of any individual fan can also be discerned.
The foregoing describes a technique for controlling the speed of a set of fans (22) cooling an electronics enclosure 10 in accordance with the difference between the actual temperature difference ΔT and the maximum allowable temperature difference value ΔTm for the current value of Ti.
It is to be understood that the above-described embodiments are merely illustrative of the principles of the invention. Various modifications and changes may be made thereto by those skilled in the art which will embody the principles of the invention and fall within the spirit and scope thereof. For example, the fan control technique of the invention is applicable for any type of enclosure, not just the enclosure 10, and may be employed to control either a single fan 22, or a multiple set of fans.
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|EP0660951A4 *||Jun 25, 1993||Nov 29, 1995||Johnson Service Co||Model-based thermobalance with feedback.|
|EP0878137A1 *||Apr 4, 1998||Nov 18, 1998||Hosokawa Kreuter GmbH||Method for cooling coated food products, especially confectionary and bakery products|
|EP2348382A3 *||Jan 10, 2011||Jan 4, 2012||Fujitsu Limited||Cooling controlling apparatus, electronic apparatus, and cooling controlling method|
|U.S. Classification||236/49.3, 361/695, 361/679.48, 165/289, 236/DIG.9|
|International Classification||G05D23/19, F24F11/00|
|Cooperative Classification||Y10S236/09, F24F11/0001, G05D23/1931|
|European Classification||F24F11/00C, G05D23/19G4B|
|Mar 28, 1991||AS||Assignment|
Owner name: AMERICAN TELEPHONE AND TELEGRAPH COMPANY, 550 MADI
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:HARVEY, WILLIAM J.;REEL/FRAME:005661/0956
Effective date: 19910327
|Aug 31, 1995||FPAY||Fee payment|
Year of fee payment: 4
|Oct 4, 1999||FPAY||Fee payment|
Year of fee payment: 8
|Sep 19, 2003||FPAY||Fee payment|
Year of fee payment: 12